TwingTec's path to commercialization Rolf Luchsinger, TwingTec AG
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0
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194
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June 24, 2022
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A Semi-Empirical Aerodynamic Model Based on Dynamic Stall for Rigid-Framed Delta Kites during Figure-of-Eight Maneuvers Iván Castro-Fernández , Universidad Carlos III de Madrid
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0
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191
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June 24, 2022
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Combined Experimental and Numerical Aerodynamic Optimisation of High-Performance Rigid-Wing AWE Systems Denes Fischer, Technical University Berlin
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0
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205
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June 24, 2022
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Improving Lifting-Line/Vortex-Step Methods for Kite Applications using 2D Unsteady Thin Airfoil Theory Results Mac Gaunaa, DTU
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0
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208
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June 24, 2022
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High fidelity Fluid-Structure Interaction Simulation of a Multi-megawatt Airborne Wind Energy Reference System Niels Pynaert, Ghent University
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0
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224
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June 24, 2022
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Save Japan from a Future Social Crisis! "Mothership" Project Current Development Progress Eiji Itakura, Toyota Motor Corporation
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219
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June 24, 2022
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Technical Development in Kitemill Espen Oland, Kitemill AS
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0
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220
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June 24, 2022
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Polar Wind Highways Ignacio Oficialdegui, Windsled
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0
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227
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June 24, 2022
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First Airborne Wind Energy operation on a tropical island Joep Breuer, Kitepower BV
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200
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June 24, 2022
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Automated Power Cycles in Daylong Operation at SkySails Test Site Manfred Quack, SkySails Power GmbH
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0
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169
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June 24, 2022
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Quantifying AWE Optimal Control Problem Tractability with Simple Vortex Models Rachel Leuthold, University of Freiburg
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185
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June 24, 2022
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Model Predictive Path-Following Control of Airborne Wind Energy Systems with Guaranteed Stability Manuel C.R.M. Fernandes, Universidade do Porto
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0
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177
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June 24, 2022
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Kite Path-following with L0 and L1 Controllers Tested on a Small-scale Prototype Sérgio Vinha, Universidade do Porto
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160
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June 24, 2022
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Social Acceptance of Airborne Wind Energy Helena Schmidt, TU Delft
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204
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June 24, 2022
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Rapidly Deployable Airborne Wind Energy Systems for Defense and Disaster Response Eric J. Lang, University of Dayton Research Institute
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210
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June 24, 2022
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Airborne wind energy development database Roland Schmehl, TU Delft
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0
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211
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June 24, 2022
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Fault-tolerant Control of Airborne Wind Energy Systems with Quadrotor/Fixed-Wing UAV Configuration Tareg Mohammed, Politecnico di Milano
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0
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163
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June 24, 2022
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Iterative Learning-Based Kite Path Optimization for Maximum Energy Harvesting James Reed, North Carolina State University
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0
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194
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June 24, 2022
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Estimation of Unknown Aerodynamic Forces of an AWE System Ahmad Hably, Grenoble-INP
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0
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177
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June 24, 2022
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Kernel-based Identification of Periodically Parameter-Varying Models of Power Kites Mingzhou Yin, ETH Zurich
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0
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167
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June 24, 2022
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Practicalities of Site Selection for an Offshore AWE Demonstration: A Case Study for Ireland Inés Coca-Tagarro, BlueWise Marine
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0
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179
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June 24, 2022
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Towards flow-field characterization for AWES Mark Kelly, DTU
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0
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269
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June 24, 2022
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The Airborne Wind Energy Resource Analysis Tool AWERA Lavinia Thimm, University of Bonn
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0
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182
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June 24, 2022
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True 3D high density webbing inflatable structures Rudo Enserink, enserinkdesign.com
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0
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224
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June 24, 2022
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Fostering International collaboration within IEA Wind TCP Task 48 Stefanie Thoms, Airborne Wind Europe
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209
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June 24, 2022
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